JP5705255B2 - Automatic transmission for vehicles - Google Patents

Description

  The present invention relates to an automatic transmission for a vehicle.

  As a conventional automatic transmission for a vehicle, the one described in Patent Document 1 is known. This conventional automatic transmission for a vehicle has a so-called Ravigneaux type planetary gear set and a planetary gear set consisting of a single pinion type planetary gear set, and hydraulic operation of two clutches and three brakes. The frictional engagement element according to (5) is used to obtain 6 forward speeds and 1 reverse speed.

JP 2003-240068 A

However, the conventional automatic transmission for a vehicle has the following problems.
In order to obtain each gear stage with the conventional automatic transmission for a vehicle, the engagement pressure is selectively supplied to two of the five friction engagement elements, and the remaining three friction engagement elements are in a released state. Yes. As a result, since the three frictional engagement elements in the released state are dragged, there is a problem that the fuel consumption is deteriorated accordingly. In particular, since the brake has an automatic transmission case on one side, the oil drainage is inferior to that of the clutch, resulting in higher drag resistance than the clutch. However, this conventional automatic transmission has three brakes. As a result, the fuel consumption will be further deteriorated.

  The present invention has been made paying attention to the above-mentioned problem, and the object of the present invention is to reduce the number of frictional engagement elements that generate drag in the released state, thereby improving fuel efficiency. The object is to provide an automatic transmission for a vehicle.

For this purpose, the automatic transmission for vehicles according to the present invention comprises:
An input shaft;
An output member;
A stationary part;
A first planetary gear set, a second planetary gear set, and a third planetary gear set each having three rotational elements: a sun gear, a ring gear, and a pinion carrier;
Five frictional engagement elements, a first clutch, a second clutch, a third clutch, a first brake, and a second brake;
With
The three rotating elements of the first planetary gear set are arranged on the common speed diagram according to the interval corresponding to the gear ratio of the first planetary gear set, and the first element, the second element, and the third element are arranged in this order. age,
The three rotating elements of the second planetary gear set are arranged in accordance with the interval corresponding to the gear ratio of the second planetary gear set on the common speed diagram, and the fourth element, the fifth element, and the sixth element are arranged in this order. age,
The three rotating elements of the third planetary gear set are arranged according to the interval corresponding to the gear ratio of the third planetary gear set on the common speed diagram, and the seventh element, the eighth element, and the ninth element are arranged in this order. age,
Always connect the input shaft to the second element,
Always connecting the output member to the fifth element;
The first element and the seventh element are always connected and can be fixed to the stationary part by fastening the first brake,
The third element can be connected to the fourth element by fastening the first clutch, and can be fastened to the eighth element by fastening the second clutch,
Always connect the fourth element to the ninth element,
The sixth element can be fixed to the stationary part by fastening the second brake, and can be connected to the eighth element by fastening the third clutch.
It is characterized by that.

  Preferably, the first planetary gear set to the third planetary gear set are all single-pinion type planetary gear sets.

Preferably, the first clutch is engaged at the first speed, the second speed, the fourth speed and the fifth speed,
The second clutch is engaged at the first speed, third speed, fourth speed, sixth speed and reverse,
The third clutch is engaged at the fourth speed, fifth speed, sixth speed and reverse,
The first brake is engaged at the second speed, the third speed, the fifth speed and the sixth speed,
The second brake is engaged at the first speed, second speed, third speed, and reverse,
It is characterized by that.

Preferably, the first element is a sun gear of the first planetary gear set,
The second element is a pinion carrier of the first planetary gear set;
The third element is the ring gear of the first planetary gear set;
The fourth element is the sun gear of the second planetary gear set;
The fifth element is the pinion carrier of the second planetary gear set;
The sixth element is the ring gear of the second planetary gear set;
The seventh element is the sun gear of the third planetary gear set;
The eighth element is the pinion carrier of the third planetary gear set;
The ninth element is the ring gear of the third planetary gear set;
It is characterized by that.

In the present invention, since the automatic transmission is configured as described above, it is possible to reduce the number of friction elements to be released to a smaller number than that of the prior art when the friction engagement elements are engaged at each shift stage.
For this reason, the drag by the frictional engagement element in the released state can be reduced and the fuel consumption can be improved.

  Further, since the first planetary gear group to the third planetary gear group are all single-pinion type planetary gear groups, the structure is simplified, which is advantageous in terms of sound and vibration.

In addition, since the frictional engagement elements of the first to third clutches, the first brake, and the second brake are engaged as described above, it is possible to obtain six forward speeds and reverse gears.
In this case, in order to obtain each shift stage, it is only necessary to fasten the three frictional engagement elements and release the remaining two, so that one frictional engagement element in the dragged state is one in comparison with the prior art. This can reduce the fuel consumption. Further, fuel consumption can be further improved as the number of brakes is reduced.

  In addition, since the first to ninth elements are configured as described above, an automatic transmission with an optimum gear ratio can be obtained.

It is a figure which shows the skeleton of the automatic transmission for vehicles which concerns on Example 1 of this invention. It is a figure showing the action | operation table | surface which shows the action | operation of the friction engaging element used with the automatic transmission for vehicles of Example 1, and the gear in each gear stage. FIG. 3 is a common speed diagram at a first forward speed in the automatic transmission for a vehicle according to the first embodiment. FIG. 3 is a common speed diagram at a second forward speed in the vehicle automatic transmission according to the first embodiment. FIG. 3 is a common speed diagram at a third forward speed in the vehicle automatic transmission according to the first embodiment. FIG. 5 is a common speed diagram at a fourth forward speed in the vehicle automatic transmission according to the first embodiment. FIG. 6 is a common speed diagram at the fifth forward speed in the vehicle automatic transmission according to the first embodiment. FIG. 5 is a common speed diagram at a sixth forward speed in the vehicle automatic transmission according to the first embodiment. FIG. 3 is a reverse common speed diagram in the vehicle automatic transmission according to the first embodiment.

  Hereinafter, embodiments of the present invention will be described in detail based on examples shown in the drawings.

First, the overall configuration of the vehicle automatic transmission according to the first embodiment will be described.
The automatic transmission for a vehicle according to the first embodiment is applied to a so-called horizontal engine type of an engine front-mounted front wheel drive vehicle or an engine rear-mounted rear wheel drive vehicle.
FIG. 1 shows a skeleton of the automatic transmission for a vehicle according to the first embodiment. In FIG. 1, the upper half is drawn from the central axis (the axis passing through the central axis of the input shaft I), and the lower half is omitted.

As shown in the figure, the vehicle automatic transmission of the first embodiment includes an input shaft I, an output member O, a first planetary gear set 1, a second planetary gear set 2, and a third planetary gear set 3. A hydraulically operated frictional engagement element comprising three planetary gear sets, three clutches including a first clutch 4, a second clutch 5, a third clutch 6, a first brake 7, a second brake 8, and two brakes. And an automatic transmission case 9 (corresponding to the stationary part of the present invention) 9.
The input shaft I can be connected to an engine (not shown) via a torque converter or the like, and the output member O is composed of a gear fixed to the pinion carrier 24 of the second planetary gear set 2 and is not shown. And connected to the drive wheel via a differential gear device.

The first planetary gear set 1, the second planetary gear set 2, and the third planetary gear set 3 all use a so-called single-pinion type planetary gear set, and are away from the engine side (rightward in FIG. 1). ) Are arranged concentrically in the above order.
The first planetary gear set 1 includes three rotating elements, that is, a first sun gear 11 disposed on the center side, a first ring gear 12 disposed on the radially outer side, and a first sun gear. 11 and a first ring gear 12, and a first pinion carrier 14 rotatably supporting a plurality of first pinions 13 meshing with both of them.

  The second planetary gear set 2 includes three rotating elements, that is, a second sun gear 21 disposed on the center side, a second ring gear 22 disposed on the radially outer side, and a second sun gear. And a second pinion carrier 24 which is disposed between 21 and the second ring gear 22 and rotatably supports a plurality of second pinions 23 which mesh with both of them.

  The third planetary gear set 3 includes three rotating elements, that is, a third sun gear 31 disposed on the center side, a third ring gear 32 disposed on the radially outer side, and a third sun gear. And a third pinion carrier 34 rotatably disposed between the third ring gear 32 and the third ring gear 32 and meshing with both of them.

The rotating elements of the first planetary gear set 1 to the third planetary gear set 3 are connected, connectable and fixable as described below.
First, in the first planetary gear set 1, the first sun gear 11 is always connected to the third sun gear 31, and these sun gears 11, 31 are engaged with the first brake 7. Can be fixed to the case 9 of the automatic transmission.
The first ring gear 12 can be connected to the second sun gear 21 by fastening the first clutch 4 and can be connected to the third pinion carrier 34 by fastening the second clutch 5.
The first pinion carrier 14 is always connected to the input shaft I.
Here, the gear ratio α1 of the first planetary gear set 1 (the gear ratio of the first sun gear 11 / the gear ratio of the first ring gear 12) is set to 0.658, for example.

In the second planetary gear set 2, the second sun gear 21 can be connected to the first ring gear 12 by engaging the first clutch 4 as described above, and is connected to the third ring gear 32. Always connected.
The second ring gear 22 can be connected to the third pinion carrier 34 by fastening the third clutch 6 and can be fixed to the case 9 by fastening the second brake 8.
As described above, the output member O made of an output gear is integrally fixed to the side of the second pinion carrier 24.
Here, the gear ratio α2 of the second planetary gear set 2 (the gear ratio of the second sun gear 21 / the gear ratio of the second ring gear 22) is set to 0.416, for example.

In the third planetary gear set 3, the third sun gear 31 is always connected to the first sun gear 11 as described above, and these can be fixed to the case 9 by fastening the first brake 7. It is.
The third ring gear 32 is always connected to the second sun gear 21 as described above.
The third pinion carrier 34 can be connected to the first ring gear 12 by engaging the second clutch 5 as described above, and can be connected to the second ring gear 22 by engaging the third clutch 6. .
Here, the gear ratio α3 (the gear ratio of the third sun gear 31 / the gear ratio of the third ring gear 32) of the third planetary gear set 3 is set to 0.433, for example.

The engagement / release of each frictional engagement element in the automatic transmission of the first embodiment connected as described above is shown in the operation table of FIG. The operation table represents each speed stage from the first speed to the sixth speed and the reverse in the horizontal direction, and the friction engagement elements are arranged in the vertical direction. In the operation table, ◯ indicates that the frictional engagement element is brought into the engaged state, and blank indicates that the frictional engagement element is in the released state.
Below the operation table, the gear ratio of each gear, the ratio coverage in the automatic transmission (R / C: full gear ratio width, the gear ratio of the first forward speed is the gear ratio of the highest gear. The value divided by 1) and the reverse ratio / 1st speed ratio (Rev / 1st) are described.

  Further, the engagement and release of the friction engagement elements are controlled by supplying and removing pressure oil from a control valve (not shown) that is electronically controlled by a controller (not shown). Since the configuration and operation of these controllers and control valves are well known, their description is omitted here.

Next, the power transmission path in each gear stage will be described using the common speed diagram at that time.
Here, the common speed diagram is such that the vertical axis represents the rotational speed of each rotating element, and the horizontal axis represents these rotating elements with the gear ratios α1 to α3 of the first to third planetary gear sets 1 to 3. It is the diagram allocated according to.
That is, on the horizontal axis, in the case of a single-pinion type planetary gear set, the rotational speed axes of the three rotating elements of the ring gear, the pinion carrier, and the sun gear are arranged in this order (in either the left or right direction). If the size between the ring gear and the pinion carrier is the gear ratio α of this planetary gear set, the size between the pinion carrier and the sun gear is set apart at a ratio of 1. Is.
In this case, on the vertical axis, the rotational speed in the same rotational direction as the engine is taken above the rotational speed zero, and the rotational speed in the reverse rotational direction from the engine is taken below the rotational speed zero.
In the common speed diagram, the meshing relationship of the ring gear, pinion, and sun gear is a linear relationship in which the teeth mesh with each other on a one-to-one basis. It becomes a linear relationship.

  Further, in FIGS. 3 to 9 showing the common speed diagrams of the respective speed stages, the third planetary gear set 3, the first planetary gear set 1, and the second planetary gear are arranged from the left side to the right side in FIG. They are arranged in the order of set 2. These sun gears are represented by S, pinion carriers are represented by C, ring gears are represented by R, and these subscripts 1, 2, and 3 are the planetary gear sets to which each belongs. Numbers (first, second, third) are represented.

That is, the sun gear 11 of the first planetary gear set 1 is represented by S1, the pinion carrier 14 is represented by C1, and the ring gear 12 is represented by R1, which are respectively the first element, the second element, and the third element of the present invention. It corresponds to.
The sun gear 21 of the second planetary gear set 2 is represented by S2, the pinion carrier 24 is represented by C2, and the ring gear 22 is represented by R2. These correspond to the fourth, fifth and sixth elements of the present invention, respectively. To do.
In the third planetary gear set 3, the sun gear 31 is represented by S3, the pinion carrier 34 is represented by C3, and the ring gear 32 is represented by R3, which correspond to the seventh, eighth, and ninth elements of the present invention, respectively. To do.

  Therefore, the common velocity diagram is the seventh element, the eighth element, the ninth element, the first element, the second element, the third element from the left side to the right side in FIG. Speed axes corresponding to the fourth element, the fifth element, and the sixth element are arranged. In each of the common velocity diagrams of FIGS. 3 to 9, the input is indicated by ◯ and the output is indicated by Δ. The rotational speed of the input shaft I is set to 1 in the common speed diagram for easy calculation of the gear ratio. Further, the gear ratios at the following shift speeds are values when α1 to α3 are set to 0.658, 0.416, and 0.433, respectively, as described above.

  First, when the automatic transmission is in the N (neutral) position or the P (park) position, since no fastening pressure is supplied to all the friction engagement elements, the first planetary gear set 1 to the third planetary gear set 3 are They are all free and do not transmit power. As a result, the power from the engine is not transmitted to the output member O.

When the driver moves a select lever (not shown) to a D (drive, that is, forward travel) position, the vehicle starts. Since the vehicle speed is low at the time of starting, first speed is established.
That is, at the first speed, the first clutch 4, the second clutch 5, and the second brake 8 are respectively engaged.
Accordingly, the first ring gear 12 and the second sun gear 21 are connected by the first clutch 4, and these and the third ring gear 32 connected to the second sun gear 21 rotate at the same rotational speed. To do.
Further, the engagement of the second clutch 5 causes the first ring gear 22 to rotate at the same rotational speed as the third pinion carrier 34.
Further, since the first sun gear 11 and the third sun gear 31 are connected, they rotate at the same rotational speed.
Therefore, all the rotating elements of the first planetary gear set 1 and the third planetary gear set 3 are united and rotate at the same rotational speed 1 as the rotational speed of the input shaft I.
On the other hand, in the second planetary gear set 2, the second sun gear 21 rotates at the same rotational speed 1 as the first ring gear 12 when the first clutch 4 is engaged. In this case, since the second ring gear 22 is fixed to the case 9 by the engagement of the second brake 8 and the rotational speed becomes zero, the output member O is rotated at the rotational speed of the second pinion carrier 24 to which the output member O is connected, that is, The straight line connecting the rotational speed 1 on the speed axis of S2 and the rotational speed 0 on the speed axis of R2 rotates at the rotational speed at the point where it intersects the speed axis of C2. As is apparent from FIG. 3, in this case, the automatic transmission drives the vehicle at the first forward speed that is the most decelerated gear ratio 3.406.

When the vehicle speed increases, the controller releases the second clutch 5 and engages the first brake 7 to shift from the first speed to the second speed. At this time, the engagement of the first clutch 4 and the second brake 8 remains at the first speed. A common velocity diagram in this state is shown in FIG.
When the first brake 7 is engaged, the first sun gear and the third sun gear 31 are fixed to the case 9 and have a rotational speed of zero.
At the second speed, in the first planetary gear set 1, the first pinion carrier 14 rotates at the same rotational speed 1 as the input shaft I, and the rotational speed of the first sun gear 11 is 0 as described above. The first ring gear 12 rotates at an overdrive rotational speed faster than that of the input shaft I.
As a result, in the second planetary gear set 2, the second sun gear 21 rotates at the same overdrive rotational speed as the first ring gear 12 connected by the engagement of the first clutch 4. At this time, since the rotation speed of the second ring gear 22 is 0 when the second brake 8 is engaged, the straight line connecting the overdrive rotation speed of the second sun gear 21 and the rotation speed 0 of the second ring gear 22 The point where the speed axis C2 of the second pinion carrier 24 intersects is the rotational speed of the second pinion carrier 24 and the output member O connected thereto.
That is, as is apparent from FIG. 4, the output member O rotates at the second speed (gear ratio 2.054) that is a reduced rotational speed faster than the first speed.
In the third planetary gear set 3, the third sun gear 31 is fixed to the case 9 when the first brake 7 is engaged, and the rotational speed is zero, and the third ring gear 32 is the second sun gear 21. And the third pinion carrier 34 rotates at an overdrive rotational speed that is slower than that of the third ring gear 32.

When the vehicle speed further increases and the controller releases the first clutch 4 and engages the second clutch 5, the automatic transmission changes from the second speed to the third speed. At this time, the engagement of the first brake 7 and the second brake 8 is maintained as it is. A common velocity diagram in this state is shown in FIG.
That is, at the third speed, the first planetary gear set 1 is the same as at the second speed.
On the other hand, in the third planetary gear set 3, the third sun gear 31 is fixed to the case 9 by the engagement of the first brake 7 and the rotational speed becomes zero, and the third pinion carrier 34 is engaged with the second clutch 5. Is connected to the first ring gear 12 and rotates at the same overdrive rotational speed, so that the third ring gear 32 rotates at an overdrive rotational speed faster than the third pinion carrier 34.
In the second planetary gear set 2, the second ring gear 22 is fixed to the case 9 when the second brake 8 is engaged and the rotational speed is zero, and the second sun gear 21 is connected to the third ring gear 32. Therefore, the second pinion carrier 24 and the output O integrated with the second pinion carrier 24 rotate at the third speed (gear ratio 1.433) which is a reduced rotational speed faster than the second speed. .

When the vehicle speed further increases and the controller releases both the first brake 7 and the second brake 8, and the first clutch 4 and the third clutch 6 are engaged, the automatic transmission changes from the third speed to the fourth speed. Become. At this time, the engagement of the second clutch 5 is maintained as it is. A common velocity diagram in this state is shown in FIG.
In the fourth speed, the first ring gear 12 and the second sun gear 21 are engaged by the engagement of the first clutch 4, and the third ring gear 32 connected to the second sun gear 21 is all at the same rotational speed. Rotate with.
Further, the first ring gear 12 and the third pinion carrier 34 are connected by the engagement of the second clutch 5, and the third pinion carrier 34 and the second ring gear 22 are connected by the engagement of the third clutch 6. As a result of the connection, the first ring gear 12, the third pinion carrier 34, and the second ring gear 22 rotate at the same rotational speed.
As a result, all the rotating elements of the first planetary gear set 1, the second planetary gear set 2, and the third planetary gear set 3 rotate together at the same rotational speed as the input shaft I.
Therefore, the output member O rotates at the fourth speed (gear ratio 1, that is, direct coupling ratio) that is the same rotational speed as the input shaft I.

When the vehicle speed further increases and the controller releases the second clutch 5 and the first brake 7 is engaged, the automatic transmission changes from the fourth speed to the fifth speed. At this time, the engagement of the first clutch 4 and the third clutch 6 is maintained as it is. A common velocity diagram in this state is shown in FIG.
At the fifth speed, the first planetary gear set 1 becomes the same as the second speed and the third speed by engaging the first brake 7.
On the other hand, in the third planetary gear set 3, when the first brake 7 is engaged, the third sun gear 31 has a rotational speed of 0, and when the first clutch 4 is engaged, the third ring gear 32 becomes the second sun gear. Since it rotates at the same overdrive rotational speed as 21 and the first ring gear 12, its third pinion carrier 34 rotates at an overdrive rotational speed that is slower than the overdrive rotational speed of the third ring gear 32.
In the second planetary gear set 2, the second sun gear 21 is connected to the third ring gear 32 and rotates at the same overdrive rotational speed, and the second ring gear is engaged by engaging the third clutch 6. Since 22 is connected to the third pinion carrier 34 and rotates at an overdrive rotational speed lower than the overdrive rotational speed, the second pinion carrier 24 and the output member O integrated with the second pinion carrier 24 have their overdrive rotational speeds. It rotates at the 5th speed (gear ratio 0.767) which becomes the overdrive rotation speed between the speeds.

When the vehicle speed further increases and the controller releases the first clutch 4 and engages the second clutch 5, the automatic transmission changes from the fifth speed to the sixth speed. At this time, the engagement of the third clutch 6 and the first brake 7 is maintained as it is. A common velocity diagram in this state is shown in FIG.
At the sixth speed, the first planetary gear set 1 becomes the same as the second speed, the third speed, and the fifth speed by engaging the first brake 7.
On the other hand, in the third planetary gear set 3, when the first brake 7 is engaged, the third sun gear 31 is at a rotational speed of 0, and when the second clutch 5 is engaged, the third pinion carrier 34 is moved to the first ring. Since the third ring gear 32 rotates at the same overdrive rotational speed as the gear 12, the third ring gear 32 rotates at an overdrive rotational speed that is faster than the overdrive rotational speed of the third pinion carrier 34.
In the second planetary gear set 2, the second sun gear 21 is connected to the third ring gear 32 and rotates at the same fast overdrive rotational speed, and the second clutch 5 and the third clutch 6 are engaged. The second ring gear 22 is connected to the third pinion carrier 34 and the first ring gear 12 and rotates at the overdrive rotational speed, so that the second pinion carrier 24 and the output member O integrated therewith are provided. Rotates at a sixth speed (gear ratio 0.535) between these overdrive rotational speeds and at an overdrive rotational speed faster than the fifth speed.

  The above describes the operation of the upshift at the D position, but the downshift at the D position is the operation in the opposite direction to the above, but the operation at each shift stage is the same, so the description thereof Is omitted.

Next, when the driver moves the select lever to the R (reverse: reverse) position while the vehicle is stopped, the controller engages the second clutch 5, the third clutch 6, and the second brake 8. A common velocity diagram in this state is shown in FIG.
During this reverse travel, in the first planetary gear set 1, the first ring gear 12 is connected to the second ring gear 22 through the third pinion carrier 34 by the engagement of the second clutch 5 and the third clutch 6. When the second brake 8 is engaged, the rotation speed is zero, and the first pinion carrier 14 is connected to the input shaft I. Therefore, the first sun gear 11 rotates at the overdrive rotation speed.
In the third planetary gear set 3, the rotation speed of the third pinion carrier 34 is 0 by the engagement of the third clutch 6 and the second brake 8 as described above, and the third sun gear 31 is connected to the first sun gear 31. Since it is connected to the gear 11 and rotates at the same overdrive rotational speed, the third ring gear 32 rotates at an overdrive rotational speed in the direction opposite to the engine drive direction.
In the second planetary gear set 2, the second ring gear 22 has a rotational speed of 0 when the second brake 8 is engaged, and the second sun gear 21 is connected to the third ring gear 32 and is the same as this. The second pinion carrier 24 and the output member O integrated with the second pinion carrier 24 and the output member O integrated with the second pinion carrier 24 rotate in the direction opposite to the driving direction of the engine rotating speed. Rotates at the reverse speed (gear ratio -3.119, where-represents the direction of rotation opposite to the driving direction of the engine rotation speed) at the reduced rotation speed in the direction.

In the automatic transmission of the first embodiment, the ratio coverage (R / C value) is 6.365, starting at low speed, climbing performance, and reducing engine noise at high speed, The fuel consumption can be improved.
Also, the reverse ratio / 1st gear ratio (Rev / 1st) is 0.916, and there is almost no difference in output with respect to the amount of depression of the accelerator pedal at the time of start and reverse, so the driver does not feel uncomfortable .

As described above, the automatic transmission according to the first embodiment has the following effects.
That is, in the automatic transmission according to the first embodiment, the number of frictional engagement elements that generate drag in the released state is reduced from three to two in the prior art, so that fuel efficiency can be improved. it can.
In addition, although there are five frictional engagement elements as in the prior art, the conventional one has three hydraulically operated brakes, whereas the first embodiment has two, so the drag is more than the clutch. By reducing the number of large brakes, fuel efficiency can be further improved.

  In the automatic transmission of the first embodiment, the ratio coverage (R / C value) is 6.365, and a wide gear ratio can be obtained from the low speed stage to the high speed stage. In addition, climbing performance, engine noise at high speeds, and fuel efficiency can be improved.

  Further, in the automatic transmission of the first embodiment, the reverse ratio / 1st speed ratio (Rev / 1st) is 0.916, and the output difference with respect to the accelerator pedal depression amount at the time of start and reverse Since there is almost no, it can prevent the driver from feeling uncomfortable.

  As described above, the present invention has been described based on the above-described embodiments. However, the present invention is not limited to the above-described embodiments, and even if there is a design change or the like without departing from the gist of the present invention, the present invention is included.

For example, the first planetary gear set 1 to the third planetary gear set 3 are not limited to the single pinion type, and may be a double pinion type planetary gear set.
Further, the first to ninth elements of the present invention may be applied with a rotating element different from that of the embodiment.
Further, the values of α1 to α3 are not limited to the values in the embodiment, and may be appropriately changed as necessary.

  Further, the automatic transmission of the present invention is not limited to an engine front-mounted front wheel drive vehicle or an engine rear-mounted rear wheel drive vehicle.

I Input shaft
O Output member
1 First planetary gear set
11 First sun gear (first element)
12 1st ring gear (3rd element)
13 First pinion
14 1st pinion carrier (2nd element)
2 Second planetary gear set
21 2nd sun gear (4th element)
22 Second ring gear (sixth element)
23 Second pinion
24 2nd pinion carrier (5th element)
3 Third planetary gear set
31 3rd sun gear (7th element)
32 3rd ring gear (9th element)
33 3rd pinion
34 3rd pinion carrier (8th element)
4 First clutch
5 Second clutch
6 Third clutch
7 First brake
8 Second brake
9 Case (stationary part)

Claims (4)

An input shaft;
An output member;
A stationary part;
A first planetary gear set, a second planetary gear set, and a third planetary gear set each having three rotational elements: a sun gear, a ring gear, and a pinion carrier;
Five frictional engagement elements, a first clutch, a second clutch, a third clutch, a first brake, and a second brake;
With
The three rotating elements of the first planetary gear set are arranged on the common velocity diagram according to the interval corresponding to the gear ratio of the first planetary gear set, and the first element, the second element, the second element are arranged in this order. 3 elements
The three rotating elements of the second planetary gear set are arranged on the common velocity diagram according to the interval corresponding to the gear ratio of the second planetary gear set, and the fourth element, fifth element, 6 elements,
The three rotating elements of the third planetary gear set are arranged according to the interval corresponding to the gear ratio of the third planetary gear set on the common velocity diagram, and the seventh element, the eighth element, 9 elements,
Always connecting the input shaft to the second element;
Always connecting the output member to the fifth element;
The first element and the seventh element are always connected, and can be fixed to the stationary part by fastening the first brake,
The third element can be connected to the fourth element by fastening the first clutch, and can be fastened to the eighth element by fastening the second clutch;
Always connecting the fourth element to the ninth element;
The sixth element can be fixed to a stationary part by fastening the second brake, and can be connected to the eighth element by fastening a third clutch.
The automatic transmission for vehicles characterized by the above-mentioned. The automatic transmission for a vehicle according to claim 1,
The first planetary gear set to the third planetary gear set are all single-pinion type planetary gear sets.
The automatic transmission for vehicles characterized by the above-mentioned. The automatic transmission for a vehicle according to claim 1 or 2,
The first clutch is engaged at the first speed, the second speed, the fourth speed and the fifth speed,
The second clutch is engaged at first speed, third speed, fourth speed, sixth speed and reverse,
The third clutch is engaged at the fourth, fifth, sixth and reverse speeds;
The first brake is engaged at the second speed, the third speed, the fifth speed and the sixth speed,
The second brake is engaged at the first speed, the second speed, the third speed, and reverse,
The automatic transmission for vehicles characterized by the above-mentioned. The automatic transmission for a vehicle according to any one of claims 1 to 3,
The first element is a sun gear of the first planetary gear set;
The second element is a pinion carrier of the first planetary gear set;
The third element is a ring gear of the first planetary gear set;
The fourth element is a sun gear of the second planetary gear set;
The fifth element is a pinion carrier of the second planetary gear set;
The sixth element is a ring gear of the second planetary gear set;
The seventh element is a sun gear of the third planetary gear set;
The eighth element is a pinion carrier of the third planetary gear set;
The ninth element is a ring gear of the third planetary gear set;
The automatic transmission for vehicles characterized by the above-mentioned.

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